Composite cable

ABSTRACT

A composite cable which makes it possible to improve disconnection resistance of a signal line. The composite cable includes a signal line part, a pair of power supply lines, and a sheath. The signal line part is composed of a first signal line and a second signal line twisted together. Each of the first signal line and the second signal line is composed of a pair of wires twisted together. The sheath covers an outer circumference of a wire bundle composed of the signal line part and a pair of power supply lines, the signal line part and the pair of power supply lines being twisted together. The signal line part is covered with a shield conductor formed of a braid composed of a plurality of conductive element wires braided together.

CROSS-REFERENCE

The present application claims priority under 35 U.S.C. § 119 to Japanese Application No. 2018-058368, filed on Mar. 26, 2018, entitled “ COMPOSITE CABLE”. The contents of this application are incorporated herein by reference in their entirety.

TECHNICAL FIELD

The present invention relates to a composite cable.

BACKGROUND ART

In recent years, an electric brake electrically controlled has attracted attention in automobile field. For example, Patent Document 1 discloses a composite cable for use in an electric brake, which includes one signal line that is composed of a pair of wires and is connected to a sensor for measuring a rotation velocity of a wheel, and two power supply lines connected to a brake caliper.

PRIOR ART LITERATURE Patent Document

Patent Document 1 Japanese Patent No. 5594446

SUMMARY OF THE INVENTION

Whereas, in the conventional composite cable, for example, when one end side of the cable is fixed to a vehicle body, and the other end side of the cable is attached to a portion around a wheel where vertical vibration arises, the cable is also subjected to vibration caused by multiple shaking mainly including large horizontal shaking of the cable (shaking in a longitudinal direction of an automobile) when subjected to vertical vibration in a bending state. For this reason, the conventional composite cable has such an issue that the signal line is easily disconnected around a portion for fixing the cable.

The present invention has been made in view of such a background, and it is intended to provide a composite cable which makes it possible to improve disconnection resistance of a signal line.

One aspect of the present invention is a composite cable, including:

a signal line part including a first signal line composed of a pair of wires twisted together;

a pair of power supply lines;

a sheath that covers an outer circumference of a wire bundle composed of the signal line part and the pair of power supply lines, the signal line part and the pair of power supply lines being twisted together;

wherein the signal line part is covered with a shield conductor formed of a braid composed of a plurality of conductive element wires braided together.

Effects of the Invention

The composite cable has the above-mentioned configuration. In particular, the signal line part of the composite cable has its outer circumference covered with a shield conductor formed of a braid composed of a plurality of conductive element wires braided together. In the composite cable, the rigidity of the cable is improved by the shield conductor in comparison with the conventional composite cable that has no shield conductor provided. Consequently, it is made possible to restrain the horizontal shaking of the composite cable when subjected to vertical vibration in a bending state. In addition, because the shield conductor is restricted in movement of the conductive element wires when the cable is horizontally shaking so as to hardly produce gaps between the winding of the element wires, the composite cable is excellent in torsion resistance.

Accordingly, the composite cable 1 makes it possible to enhance the disconnection resistance of the first signal line 21.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an illustration schematically showing a composite cable according to Embodiment 1 in a cross section perpendicular to the center axis of the cable.

FIG. 2 is an illustration schematically showing an external view of a signal line covered with a shield conductor in the composite cable according to Embodiment 1.

FIG. 3 is an illustration schematically showing an application example of the composite cable according to Embodiment 1.

FIG. 4 is an illustration schematically showing a composite cable according to Embodiment 2 in a cross section perpendicular to the center axis of the cable. FIG. 5 is an illustration schematically showing a composite cable according to Embodiment 3 in a cross section perpendicular to the center axis of the cable.

DETAILED DESCRIPTION REPRESENTATIVE EMBODIMENTS Embodiment 1

A composite cable of Embodiment 1 will be described with reference to FIG. 1 to FIG. 3. As shown in FIG. 1 and FIG. 2, a composite cable 1 of the present embodiment includes a signal line part 2, a pair of power supply lines 3, and a sheath 4. A detailed explanation will be given hereafter. It is noted that the dotted-line circles in FIG. 1 show to be stranded wires, and the arrows represent twisting directions.

The signal line part 2 includes a first signal line 21 and a second signal line 22. Each of the first signal line 21 and the second signal line 22 is made up of a pair of wires 200 twisted together. In the present embodiment, the twisting directions of the first signal line 21 and the second signal line 22 are the same as shown in FIG. 1 And, the pair of wires 200 includes a conductor 201 and an insulator 202 that covers the outer circumference of the conductor 201, respectively. The conductor 201 is made up of a plurality of metal element wires twisted together. The metal element wires may be formed of copper or copper alloy, or aluminum or aluminum alloy, and so on. The insulator 202 may be formed of, for example, cross-linked polyethylene (PE), or the like.

The signal line part 2 is made up of the first signal line 21 and the second signal line 22 twisted together. In the present embodiment, the twisting direction of the signal line part 2 is the same as those of the first signal line 21 and the second signal line 22 as shown in FIG. 1.

As shown in FIG. 2, the signal line part 2 is covered with a shield conductor 5. The shield conductor 5 is formed of a braid composed of a plurality of conductive element wires 50 braided together. In the present embodiment, the braid serving as the shield conductor 5 is formed in a tubular shape, and is provided on the outer circumference of the signal line part 2 by inserting the signal line part 2 into the tubular-shaped braid.

Specifically, as the conductive element wires 50, a metal element wire can be used. It is noted that the metal mentioned in this specification includes any alloy. Examples of the conductive element wires 50 include, for example, a tin-plated soft copper wire, a copper alloy wire, an aluminum wire, and an aluminum alloy wire. In addition, as the conductive element wires 50, a metal foil wire, or the like formed by laterally winding a metal foil around the outer circumference of a resin fiber, can be used. As the resin fiber, for example, an aramid fiber, or the like can be exemplified. As the metal foil, a copper foil, a copper alloy foil, or the like can be exemplified. In the case where a metal foil wire is used as the conductive element wires 50, it advantageously works on improvements in the strength and flexibility of the shield conductor 5 in comparison with the case where a metal element wire is used as the conductive element wires 50. In the case where a metal element wire is used as the conductive element wires 50, it advantageously works on reduction of electric resistance, cost reduction, and so on in comparison with the case where a metal foil wire is used as the conductive element wires 50.

More specifically, in comparison between the above-mentioned tin-plated soft copper wire, the copper alloy wire, the copper foil wire (the ararnid fiber plus the copper foil) in terms of tensile strength, the copper alloy wire has higher strength approximately by three to four times than that of the tin-plated soft copper wire as a basis. The copper foil wire has higher strength approximately by six to eight times than that of the tin-plated soft copper wire. Thus, among such conductive element wires 50, the copper foil wire is suitable for enhancing the strength of the shield conductor 5. Further in comparison between the above-mentioned tin-plated soft copper wire, the copper alloy wire, the copper foil wire (the aramid fiber plus the copper foil) in terms of flexibility against repeated bending, the copper alloy wire exhibits good followability to bending, and good flexibility. The copper foil wire is more excellent in flexibility than the copper alloy wire. Thus, among such conductive element wires 50, the copper foil wire is suitable for enhancing the flexibility of the shield conductor 5. Whereas, from the viewpoints of reduction of electric resistance and cost reduction, the tin-plated soft copper wire is advantageous. It is noted that if the shield conductor 5 is made of the metal foil itself, or is made of a resin tape having a metal deposited thereon, it is broken when the composite cable 1 is subjected to vertical vibration in a bending state. The reason why the metal foil wire is excellent in flexibility in spite of using the metal foil is that the tensile load is received by the resin fiber, so that the metal foil is hardly broken.

In the present embodiment, each of the pair of power supply lines 3 includes a conductor 301 and an insulator 302 that covers the outer circumference of the conductor 301, respectively. The conductor 301 is made up of a plurality of metal element wires twisted together, The metal element wires may be formed of, for example, copper or copper alloy, or aluminum or aluminum alloy, and so on. The insulator 302 can be formed of, for example, cross-linked polyethylene (PE), etc. And, the outer diameters of the pair of power supply lines 3 are made smaller than that of the signal line part 2.

In the composite cable 1, at least the signal line part 2 having the outer circumference covered with the shield conductor 5, and the pair of power supply lines 3 are twisted together to constitute a wire bundle 6. In the present embodiment, the power supply lines 3 in pairs are in contact with each other. And, the pair of power supply lines 3 is in contact with the shield conductor 5 of the signal line part 2.

The outer circumference of the wire bundle 6 is covered with the sheath 4. The sheath 4 may be formed of, for example, polyurethane resin (PU), or the like.

In the present embodiment, in order that the cross section of the cable is easily made circular, a interposing layer 7 may be arranged between the outer circumference of the wire bundle 6 and the sheath 4. The interposing layer 7 may be formed of, for example, a cross-linked polyethylene (PE), or the like. It is noted that in the present embodiment, a space 8 is provided between the wire bundle 6 and the interposing layer 7.

In the composite cable 1 of the present embodiment, the signal line part 2 has its outer circumference covered with the shield conductor 5 formed of the braid composed of the plurality of conductive element wires 50 braided together, In addition, according to the composite cable 1, the rigidity of the cable is improved by the shield conductor 5 in comparison with the conventional composite cable that has no shield conductor provided. Consequently, it is made possible to restrain the horizontal shaking of the composite cable 1 when subjected to vertical vibration in a bending state. In addition, because the shield conductor 5 is restricted in movement of the conductive element wires 50 when the cable is horizontally shaking so as to hardly produce gaps between the winding of the element wires, the composite cable is excellent in torsion resistance.

Accordingly, the composite cable 1 makes it possible to enhance the disconnection resistance of the first signal line 21 and the second signal line 22.

In the present embodiment, the composite cable 1 can be used in such a condition, specifically as shown in FIG. 3, that one end side of the cable is fixed to a stable-side portion 91, and the other end side of the cable is attached to a vertically-vibrating portion 92. According to such a configuration, the above-mentioned operational effects can be surely obtained, so that the first signal line 21 and the second signal line 22 can be surely restrained from being disconnected around the cable fixing portion. The case of applying the composite cable 1 to an automotive electric brake will be described below. It is noted that in the automotive electric brake, a motor equipped on a brake caliper is actuated directly or indirectly by a main electronic control unit in accordance with a pedaling force of a driver, and the rotating force of the motor is converted to a mechanical pressing pressure. Consequently, the brake pad is pressed against the brake disc (in the case of a disc brake), or the brake shoe is pressed against the brake drum (in the case of a drum brake) to thereby brake the automobile.

When the composite cable 1 is applied to an automotive electric brake, the one end side of the composite cable 1 can be specifically fixed to a vehicle body or an undercarriage, the other end side of the cable may be attached to a portion around a wheel where vertical vibration arises. It is noted that the portion around a wheel specifically includes the lower portion of the suspension spring of an automobile (so-called the underbody part (a chassis) of an automobile), or the like. Further, the composite cable 1 may be fixed at one location or at plural locations on the one end side of the cable. Similarly, the composite cable 1 may be fixed at one location or at plural locations on the other end side of the cable. For fixing the composite cable 1 as mentioned above, a fixing bracket 911 may be used, and for attaching the composite cable 1 as mentioned above, an attachment bracket 922 may be used.

In the present embodiment, the main electronic control unit (a main ECU) is mounted on a vehicle body or an undercarriage. Further, a subsidiary electronic control unit(s) (a sub ECU) is(are) mounted on a wheel and/or a portion around a wheel. Still further, a wheel velocity sensor(s) for detecting the rotation velocity of the wheel is(are) mounted on a wheel and/or a portion around a wheel. In addition to the wheel velocity sensor, various sensors for measurement to acquire information necessary for control of a motor, such as a motor operation confirming sensor for confirming operation of the motor equipped on the brake caliper of the automotive electric brake, a motor temperature sensor for measuring the temperature of the motor, a motor rotation angle sensor for measuring the rotation angle of the motor, a motor current sensor for measuring the current supplied to the motor, a press sensor for detecting the braking force, and the like, are provided on a wheel and/or a portion around a wheel.

In the present embodiment, the first signal line 21 can be configured to transmit an electrical signal concerning the rotation velocity of the wheel, The second signal line 22 can be configured to transmit at least an electrical signal concerning control of the motor. The pair of power supply lines 3 can be configured to supply an electric power for driving the motor. According to this configuration, it hardly occurs that the first signal line 21 and the second signal line 22 are disconnected around the cable fixing portion even when the one end side of the composite cable 1 is fixed to the vehicle body or the undercarriage. Thus, the composite cable 1 that is advantageous for improvement in the durability of an electric brake, and enhancement of the reliability.

In the above-mentioned case, the first signal line 21 may be connected specifically to the main electronic control unit at the one end of the cable, and to the wheel velocity sensor at the other end of the cable. The second signal line 22 may be connected specifically to the main electronic control unit at the one end of the cable, and to the subsidiary electronic control unit at the other end of the cable. To the subsidiary electronic control unit, various sensors for measurement to acquire information necessary for control of the motor can be connected. It is noted that the various sensors can be connected to the subsidiary electronic control unit by a pair of sensor signal lines provided in each of the sensors. Each of the pair of the power supply lines 3 may be connected specifically to the main electronic control unit at the one end of the cable, and to the subsidiary electronic control unit at the other end of the cable. In this case, a three phase AC motor can be used as the motor, and the motor can be connected to the subsidiary electronic control by a wheel-side motor power supply line. Each of the pair of the power supply lines 3 can be otherwise connected to the main electronic control unit at the one end of the cable, and directly to the motor at the other end of the cable. As the motor In this case, a DC motor can be used, It is noted that the main electronic control unit and the subsidiary electronic control unit can be configured to be inter-communicable via the second signal line 22 of the composite cable 1.

In the case applying the composite cable 1 to an electric brake, though the electric brake can be for both of a front wheel and a rear wheel, the electric brake for a front wheel is preferable to be applied. The front wheel of an automobile turns right and left by steering. Therefore, the composite cable 1 applied to an electric brake for a front wheel is subjected not only to vertical vibration in a bending state but also to a torsional force, Because the shield conductor 5 is formed of the braid, even when the torsion force is applied, gaps between the winding of the element wires are hardly extended to attain satisfactory torsion resistance. For this reason, according to the configuration in which the composite cable 1 is applied to the electric brake for a front wheel, the above-mentioned operational effects can be fully exhibited easily.

Embodiment 2

A composite cable of Embodiment 2 will be described with reference to FIG. 4.

As shown in FIG, 4, according to the present embodiment, the composite cable 1 includes a ground wire 61. Specifically, the wire bundle 6 further includes the ground wire 61 twisted together with the signal line part 2 and the pair of power supply lines 3.

According to this configuration, the following advantages are provided. Specifically, in the case of applying the composite cable 1 to an electric brake, the shield conductor 5 of the composite cable 1 according to Embodiment 1 can be grounded on the vehicle body or the under carriage at the one end side of the cable. However, the other end side of the cable is located on the wheel side, and thus grounding of the shield conductor 5 is difficult, In contrast, in the case of the present embodiment where the wire bundle 6 includes the ground wire 61, the shield conductor 5 and the ground wire 61 can be connected at the other end side of the cable. Consequently, the above-mentioned configuration has an advantage that the shieldability brought about by the shield conductor 5 can be surely exhibited even under the condition that grounding at the wheel side of the automobile would be restricted.

It is noted that the ground wire 61 may be specifically configured to include a conductor 601 and an insulator 602 that covers the outer circumference of the conductor 601. The conductor 601 can be formed of, for example, copper or copper alloy, or aluminum or aluminum alloy. The insulator 602 can be formed of, for example, cross-linked polyethylene (Pp, or the like. Although FIG. 4 shows an example in which the ground wire 61 is arranged on the same side as the signal line part 2, the ground wire 61 may be arranged on the side opposite to the signal line part 2 with the pair of power supply lines 3 being interposed therebetween. The other configurations and operational effects are the same as those in Embodiment 1.

Embodiment 3

A composite cable of Embodiment 3 will be described with reference to FIG. 5.

As shown in FIG. 5, according to the present embodiment, the signal line part 2 of the composite cable 1 includes the first signal line 21, not including the second signal line 22. In other word, the present embodiment is an example in which the signal line part 2 is composed of the first signal line 21. Accordingly, the shield conductor 5 is formed of the braid that covers the outer circumference of the first signal line 21 serving as the signal line part 2. According to this configuration, it hardly occurs that the first signal line 21 is disconnected around the cable fixing portion even when the one end side of the composite cable 1 is fixed to the vehicle body or the undercarriage.

In the case of applying the composite cable 1 of the present embodiment to an automotive electric brake, the first signal line 21 of the composite cable 1 may be configured to transmit an electrical signal concerning the rotation velocity of a wheel, or may be configured to transmit at least an electrical signal concerning control of the motor. In the former case, the electric brake can be constituted further using any other signal line separately for transmitting at least the electrical signal concerning control of the motor in addition to the composite cable 1. Similarly, in the latter case, the electric brake can be constituted further using any other signal line separately for transmitting the electrical signal concerning the rotation velocity of a wheel in addition to the composite cable 1.

The present invention is not limited to the above-mentioned embodiments, and various modifications can be made within the scope that does not depart from the spirit of the present invention. The configurations shown in the embodiments can be arbitrarily combined with each other. 

1. A composite cable, comprising; a signal line part including a first signal line composed of a pair of wires twisted together; a pair of power supply lines; and a sheath that covers an outer circumference of a wire bundle composed of the signal line part and the pair of power supply lines, the signal line part and the pair of power supply lines being twisted together; wherein the signal line part is covered with a shield conductor formed of a braid composed of a plurality of conductive element wires braided together.
 2. The composite cable according to claim 1, wherein the signal line part further includes a second signal line composed of a pair of wires twisted together, and the first signal line and the second signal line are twisted together.
 3. The composite cable according to claim 1, wherein each conductive element wire is a metal element wire, or a metal foil wire formed by spirally winding a metal foil around an outer circumference of a resin fiber.
 4. The composite cable according to claim 2, wherein each conductive element wire is a metal element wire, or a metal foil wire formed by spirally winding a metal foil around an outer circumference of a resin fiber.
 5. The composite cable according to claim 1, wherein the wire bundle further includes a ground wire twisted together with the signal line part and the pair of power supply lines.
 6. The composite cable according to claim 4, wherein the wire bundle further includes a ground wire twisted together with the signal line part and the pair of power supply lines.
 7. The composite cable according to claim 6, wherein the shield conductor and the ground wire are connected to each other on either one end of the cable.
 8. The composite cable according to claim 1, wherein an one end side of the cable is configured to be fixed stably, and an other end side of the cable is configured to be attached to a portion where vertical vibration arises.
 9. The composite cable according to claim 2, wherein an one end side of the cable is configured to be fixed stably, and an other end side of the cable is configured to be attached to a portion where vertical vibration arises.
 10. The composite cable according to claim 3, wherein an one end side of the cable is configured to be fixed stably, and an other end side of the cable is configured to be attached to a portion where vertical vibration arises.
 11. The composite cable according to claim 4, wherein an one end side of e cable is configured to be fixed stably, and an other end side of the cable is configured to be attached to a portion where vertical vibration arises.
 12. The composite cable according to claim 1 wherein the cable is for use in an automotive electric brake, the one end side of the cable is configured to be fixed to a vehicle body or an undercarriage, and the other end side of the cable is configured to be attached to a portion around a wheel where vertical vibration arises, the first signal line is configured to transmit an electrical signal concerning a rotation velocity of a wheel, or is configured to transmit at least an electrical signal concerning control of a motor equipped on a brake caliper of the electric brake, and the pair of the power supply lines are configured to supply an electric power for driving the motor.
 13. The composite cable according to claim 2, wherein the cable is for use in an automotive electric brake, the one end side of the cable is configured to be fixed to a vehicle body or an undercarriage, and the other end side of the cable is configured to be attached to a portion around a wheel where vertical vibration arises, the first signal line is configured to transmit an electrical signal concerning a rotation velocity of a wheel, or is configured to transmit at least an electrical signal concerning control of a motor equipped on a brake caliper of the electric brake, and the pair of the power supply lines are configured to supply an electric power for driving the motor.
 14. The composite cable according to claim 4, wherein the cable is for use in an automotive electric brake, the one end side of the cable is configured to be fixed to a vehicle body or an undercarriage, and the other end side of the cable is configured to be attached to a portion around a wheel where vertical vibration arises, the first signal line is configured to transmit an electrical signal concerning a rotation velocity of a wheel, or is configured to transmit at least an electrical signal concerning control of a motor equipped on a brake caliper of the electric brake, and the pair of the power supply lines are configured to supply an electric power for driving the motor.
 15. The composite cable according to claim 2, wherein the cable is for use in an automotive electric brake, the one end side of the cable is configured to be fixed to a vehicle body or an undercarriage, and the other end side of the cable is configured to be attached to a portion around a wheel where vertical vibration arises, the first signal line is configured to transmit an electrical signal concerning a rotation velocity of a wheel, the second signal line is configured to transmit at least an electrical signal concerning control of a motor equipped on a brake caliper of the electric brake, and the pair of the power supply lines are configured to supply an electric power for driving the motor.
 16. The composite cable according to claim 4, wherein the cable is for use in an automotive electric brake, the one end side of the cable is configured to be fixed to a vehicle body or an undercarriage, and the other end side of the cable is configured to be attached to a portion around a wheel where vertical vibration arises, the first signal line is configured to transmit an electrical signal concerning a rotation velocity of a wheel, the second signal line is configured to transmit at least an electrical signal concerning control of a motor equipped on a brake caliper of the electric brake, and the pair of the power supply lines are configured to supply an electric power for driving the motor.
 17. The composite cable according to claim 12, wherein the electric brake is a front wheel electric brake.
 18. The composite cable according to claim 15, wherein the electric brake is a front wheel electric brake. 